Patent application number | Description | Published |
20130005103 | METHODS FOR FABRICATING A FINFET INTEGRATED CIRCUIT ON A BULK SILICON SUBSTRATE - Methods are provided for fabricating a FINFET integrated circuit that includes epitaxially growing a first silicon germanium layer and a second silicon layer overlying a silicon substrate. The second silicon layer is etched to form a silicon fin using the first silicon germanium layer as an etch stop. The first silicon germanium layer underlying the fin is removed to form a void underlying the fin and the void is filled with an insulating material. A gate structure is then formed overlying the fin. | 01-03-2013 |
20130032890 | SELF-ADJUSTING LATCH-UP RESISTANCE FOR CMOS DEVICES - CMOS devices ( | 02-07-2013 |
20130049142 | TRANSISTOR WITH REDUCED PARASITIC CAPACITANCE - Scaled transistors with reduced parasitic capacitance are formed by replacing a high-k dielectric sidewall spacer with a SiO | 02-28-2013 |
20130181260 | METHOD FOR FORMING N-SHAPED BOTTOM STRESS LINER - Semiconductor devices with n-shaped bottom stress liners are formed. Embodiments include forming a protuberance on a substrate, conformally forming a sacrificial material layer over the protuberance, forming a gate stack above the sacrificial material layer on a silicon layer, removing the sacrificial material layer to form a tunnel, and forming a stress liner in the tunnel conforming to the shape of the protuberance. Embodiments further include forming a silicon layer over the sacrificial material layer and lining the tunnel with a passivation layer prior to forming the stress liner. | 07-18-2013 |
20130224945 | METHODS OF FORMING BULK FINFET DEVICES WITH REPLACEMENT GATES SO AS TO REDUCE PUNCH THROUGH LEAKAGE CURRENTS - One illustrative method disclosed herein includes forming a plurality of spaced-apart trenches in a semiconducting substrate to thereby define a fin structure for the device, forming a local isolation region within each of the trenches, forming a sacrificial gate structure on the fin structure, wherein the sacrificial gate structure comprises at least a sacrificial gate electrode, and forming a layer of insulating material above the fin structure and within the trench above the local isolation region. In this example, the method further includes performing at least one etching process to remove the sacrificial gate structure to thereby define a gate cavity, after removing the sacrificial gate structure, performing at least one etching process to form a recess in the local isolation region, and forming a replacement gate structure that is positioned in the recess in the local isolation region and in the gate cavity. | 08-29-2013 |
20140015020 | METHOD FOR FORMING N-SHAPED BOTTOM STRESS LINER - Semiconductor devices with n-shaped bottom stress liners are formed. Embodiments include forming a protuberance on a substrate, conformally forming a sacrificial material layer over the protuberance, forming a gate stack above the sacrificial material layer on a silicon layer, removing the sacrificial material layer to form a tunnel, and forming a stress liner in the tunnel conforming to the shape of the protuberance. Embodiments further include forming a silicon layer over the sacrificial material layer and lining the tunnel with a passivation layer prior to forming the stress liner. | 01-16-2014 |
20140120708 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICES INCLUDING REPLACEMENT METAL GATE PROCESS INCORPORATING A CONDUCTIVE DUMMY GATE LAYER - A method of manufacturing a semiconductor device including a replacement metal gate process incorporating a conductive dummy gate layer (e.g., silicon germanium (SiGe), titanium nitride, etc.) and a related are disclosed. The method includes forming an oxide layer on a substrate; removing a gate portion of the oxide layer from the substrate in a first region of the semiconductor device; forming a conductive dummy gate layer on the semiconductor device in the first region; and forming a gate on the semiconductor device, the gate including a gate conductor disposed in the first region and directly connected to the substrate. | 05-01-2014 |
20140159052 | METHOD AND STRUCTURE FOR TRANSISTOR WITH REDUCED DRAIN-INDUCED BARRIER LOWERING AND ON RESISTANCE - Embodiments of the invention provide an improved method and structure for a transistor with reduced DIBL and R | 06-12-2014 |
20140264613 | INTEGRATED CIRCUITS AND METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH ACTIVE AREA PROTECTION - Integrated circuits and methods for fabricating integrated circuits are provided. In an embodiment, a semiconductor substrate includes a shallow trench isolation structure disposed therein. A gate electrode structure overlies semiconductor material of the semiconductor substrate. A first sidewall spacer is formed adjacent to the gate electrode structure, with a first surface of the shallow trench isolation structure exposed and spaced from the first sidewall spacer by a region of the semiconductor material. The first surface of the shallow trench isolation structure is masked with an isolation structure mask. The region of the semiconductor material is free from the isolation structure mask. A recess is etched in the region of the semiconductor material, with the isolation structure mask in place. A semiconductor material is epitaxially grown within the recess to form an epitaxially-grown semiconductor region adjacent to the gate electrode structure. | 09-18-2014 |
20150021702 | SHALLOW TRENCH ISOLATION - A semiconductor structure with an improved shallow trench isolation (STI) region and method of fabrication is disclosed. The STI region comprises a lower portion filled with oxide and an upper portion comprising a high Young's modulus (HYM) liner disposed on the lower portion and trench sidewalls and filled with oxide. The HYM liner is disposed adjacent to source-drain regions, and serves to reduce stress relaxation within the shallow trench isolation (STI) oxide, which has a relatively low Young's modulus and is soft. Hence, the HYM liner serves to increase the desired stress imparted by the embedded stressor source-drain regions, which enhances carrier mobility, thus increasing semiconductor performance. | 01-22-2015 |